The present invention refers to a set of stowable rigid sails with a aerodynamic profile shape, that find application for driving ships and for generating power from wind.
In the fluid mechanics it is known that the efficiency of the cloth sails is lower than the wings of the aeroplanes. In these wings, the difference between the lift strength and the weight permits the aeroplane to flight, because the aerodynamic limit layer of the air does not come off the profile. On the contrary, in the conventional sails in the naval sector, it the wind push which inflates the sail and produces, by thrust, a resulting strength that permits the advancement of the ship or vessel.
During long time a sail for aquatic navigation presenting the advantages of the aviation wings has been desired. To this end, there have been some attempts to provide rigid sails with an aerodynamic profile of aeronautic kind
Among them it must be cited the Flettner rotors already disclosed in 1926 by Anton Flettner (FLETTNER, Anton, “Mein Weg zum Rotor”, Leipzig (Köhler & Amelang, 1926)), cited e.g. in EP 040 597.
WO 2004024556 discloses a rigid sail comprising two parts that can be relatively rotated about a vertical axis to determine the intrados and extrados of a sail like an aerodynamic profile of those used for the wings of the aeronautic technics.
WO 0189923 discloses a rigid sail with a hinged aerodynamic profile that comprises three vertical elements (or modules), each of them being formed by three horizontal elements (or sections) hinged to each other or extrados from the rigid wing or sail.
U.S. Pat. No. 7,146,918 discloses a system for generating electric power and hydrogen from sea water and wind power, in systems floating in water comprising rigid sails.
FR 2648426 discloses a wing comprising a rigid part and a flexible part that houses inside a housing in the rigid part, permitting different aerodynamic configurations.
ES 2311399 discloses a rigid sail with a configurable profile, with closing elastic sheets, joined to the corresponding wall in at least a zone close to said end edge and means for generating and feeding pressurized air and vacuum to inflate and deflate the sails to voluntarily change the profile of the sail.
However, these attempts, from which only some illustrative examples have been cited, have not achieved yet a versatile, cheap and easy operated device. The object of the present invention is to provide a solution to this need.
To this end, the object of the invention is a set of stowable rigid sails, that is characterised in that, according to the characterising portion of claim 1, it comprises pairs of opposed sails, each comprising extensible masts, sections that longitudinally slide along said masts and panels, hinged to the sections and to each other, that conform the side surface of each sail, said panels being operative between two positions: an unfolded operative position, in which they are essentially coplanar and longitudinally aligned in a essentially vertical direction; and a folded rest position, in which they are bellows-like pilled, with the essentially horizontal sections (3).
In claims 2 and the following ones preferred embodiments of the present invention are disclosed.
It must be cited again that the rigid sails will be preferably associated with a ship hull; furthermore, the object of the invention considers during their use that one of the sails will be in an extended vertical position and other one in the folded position, for their optimal performance, and in cases with strong winds both could be folded.
The rigid sails of the invention are applicable to the movement of a ship, and they can be also applied for generating a brake effect to transform the wind power in rotation power in a turbine axis, because they are associated to turbine means.
The rigid sail according to the invention can be associated to means for generating electric power and pressurized air by respectively alternators associated to the turbines or compressors associated to them.
In the attached drawings as a non-limitative example is shown an embodiment of the rigid sails object of the invention. In said drawings:
In said drawings a ship 39 can be seen including, in this exemplary embodiment, four set of sails according to the invention. It is clear that the concept is extensible to any kind of boat with a different number of sails 1.
The rigid sails 1 of the invention have an aerodynamic profile, and they have a particular, but not exclusive, application in boats for generating mechanical and electric power, and for obtaining pressurized air as a energetic vector. To this end, the boat 39 includes a turbine 40 for generating a brake effect, thanks to the high power excess recovered by the sail profile 1 (as will be explained hereinafter), to transform the wind power in rotation mechanical energy at an axis of the turbine, that by an alternator can be converted in electric power.
To this end, the rigid sails 1, according to the invention, and as can be seen in detail in
The panels 4 are joined to the sections 3 by rotatable hinges 5, permitting the free rotation, and they are joined to each other by hinges 6, permitting also the free rotation, according to
The sections 3 are each joined with the following one by struts 7; an end of each strut 7 is fixed by the internal part to each of the sections 3, and the other end is moved by the holes 8 placed inside the sections 3 until it abuts against the housing 9 placed at the upper part of the sections 3.
At the ends of each upper length of each of the masts 2 a base 11 is fixed, with the pulleys 12 and a carcass 13.
Through the pulleys 12 a cable 18 slides, from which an end is fixed to the upper section 3 by the anchorage 19 and the other is fixed to the base 14 by the anchorage 20, and said base is integral with the second length of the telescopic mast 2.
At the carcass 13 is fixed an elastic envelope 21, fixed at one end to the carcass 13 and at the other end to the upper section 3, which when the sails are folded, according to
For the unfolded position of the sails 1, the last length of the panel of the output edge 24, according to
Regarding the attack edge, along the whole vertical length of the panels 4, they are joined by the hinges 31 to the curved panels 27. In the working position (unfolded) of sails 1, so that the panels 27 are adapted to the shape of the sections 3, cylinders 26 are used, which define by the struts 28 the perfect adaptation to the previously cited shape, according to
For the folding, it is necessary to move all the needed panels of the intrados part, because in their original position they do not permit said folding because there is a superposition to each other, because they are at the inner curve zone; in the example shown, said panels 4 are joined to the pieces 33 and 36, which are fixed to the sections 3 by the hinges 34. For the movements, cylinders or actuators 35 are used, which are fixed at an end to the sections 3 by hinges 37, and at the other end by pieces 33 and/or 36 by hinges 38.
According to
As the nature of the present invention is described enough, and also the way for put it in practice, it is pointed out and anything that do not alter, change or modify its main principle is subjected to detail variations, according to the scope of protection defined in the attached claims.
Number | Date | Country | Kind |
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P200900791 | Mar 2009 | ES | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/ES10/00121 | 3/15/2010 | WO | 00 | 11/21/2011 |